Electroluminescent Zinc(II) Bis(8-hydroxyquinoline): Structural Effects on Electronic States and Device Performance

Abstract

We present direct evidence for stable oligomers in vacuum-deposited thin films of zinc(II) bis(8-hydroxyquinoline) (Znq₂). The tetramer [(Znq₂)₄] is the energetically favored configuration in both the single crystal and the vacuum-deposited thin film. Oligomerization leads to distinct, symmetry-driven differences between the electronic states in Znq₂ and those in the archetypal organic electroluminescent molecule tris(8-hydroxyquinoline) aluminum (Alq₃). In the case of the Znq₂ tetramer, symmetry leads to an extended network of overlapping pyridyl and phenolato moieties in the solid film. Analysis of the electronic structure of (Znq₂)₄ calculated by ab initio Hartree−Fock (HF) methods reveals a localization and energy shift of high-lying occupied and low-lying unoccupied states on symmetry related ligands located on opposite sides of the supramolecular structure resulting in a dipole moment for (Znq₂)₄ tetramer close to zero. The optimal π-overlap pathways, altered charge distributions, and extended electronic states of tetrameric Znq₂ may be expected to enable low operating voltage organic light-emitting devices (OLEDs) based on Znq₂. We present preliminary evidence that the operating voltage of (Znq₂)₄-based OLEDs is indeed lower than that of identical devices made with Alq₃. Strategic substitution of 8-hydroxyquinoline ligands and control of the structural symmetry of the corresponding metal chelates may offer a route to high efficiency and low operating voltage small molecule OLEDs.